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Chronic heat stress induces renal fibrosis and mitochondrial dysfunction in laying hens
Journal of Animal Science and Biotechnology volume 14, Article number: 81 (2023)
Abstract
Background
Heat stress in laying hens negatively affects egg production and shell quality by disrupting the homeostasis of plasma calcium and phosphorus levels. Although the kidney plays an important role in calcium and phosphorus homeostasis, evidence regarding the effect of heat stress on renal injury in laying hens is yet to be elucidated. Therefore, the aim of this study was to evaluate the effects of chronic heat stress on renal damage in hens during laying periods.
Methods
A total of 16 white-leghorn laying hens (32 weeks old) were randomly assigned to two groups (n = 8). One group was exposed to chronic heat stress (33 °C for 4 weeks), whereas the other group was maintained at 24 °C.
Results
Chronic heat exposure significantly increased plasma creatinine and decreased plasma albumin levels (P < 0.05). Heat exposure also increased renal fibrosis and the transcription levels of fibrosis-related genes (COLA1A1, αSMA, and TGF-β) in the kidney. These results suggest that renal failure and fibrosis were induced by chronic heat exposure in laying hens. In addition, chronic heat exposure decreased ATP levels and mitochondrial DNA copy number (mtDNA-CN) in renal tissue, suggesting that renal mitochondrial dysfunction occurs under conditions of heat stress. Damaged mitochondria leak mtDNAs into the cytosol and mtDNA leakage may activate the cyclic GMP-AMP synthase (cGAS) stimulator of interferon genes (STING) signaling pathway. Our results showed that chronic heat exposure activated the cGAS-STING pathway as indicated by increased expression of MDA5, STING, IRF7, MAVS, and NF-κB levels. Furthermore, the expression of pro-inflammatory cytokines (IL-12) and chemokines (CCL4 and CCL20) was upregulated in heat-stressed hens.
Conclusions
These results suggest that chronic heat exposure induces renal fibrosis and mitochondrial damage in laying hens. Mitochondrial damage by heat stress may activate the mtDNA-cGAS-STING signaling and cause subsequent inflammation, which contributes to the progression of renal fibrosis and dysfunction.
Background
Heat stress is one of the most deleterious environmental stressors affecting the poultry industry worldwide [1], because poultry is highly sensitive to heat stress and their ability to dissipate body heat is low [2]. Heat stress decreases the egg weight and shell quality in laying hens [3]. Moreover, exposure of laying hens to a high temperature causes a decrease in the plasma calcium and phosphorus levels [4], which are important minerals for laying hens that affect egg production and shell quality [5, 6]. The kidney plays an important role in maintaining calcium and phosphorus homeostasis, which is balanced by gastrointestinal absorption and renal excretion [7]. Therefore, low plasma calcium and phosphorus levels in hens exposed to chronic heat stress may be associated with renal dysfunction. However, there remains a lack of evidence demonstrating an effect of heat stress on renal damage in laying hens.
The kidney requires a large amount of energy because of the reabsorption of ultrafiltrate by the glomeruli to maintain homeostasis [8]; thus, mitochondria are enriched in renal tubular cells. Mitochondria are key organelles involved in various processes related to energy production from free radicals and signal transduction [9]. Mitochondrial dysfunction causes increased oxidative stress, depletion of ATP, and cell death [10], which are associated with various health issues, such as cancer [11], cardiovascular disease [12], Alzheimer’s disease [13], neurodegeneration [14], and aging [15]. Recent studies showed a pathogenic role for mitochondrial damage in the development and progression of kidney disease in humans and mice [16], indicating that mitochondrial homeostasis and biogenesis are essential for maintaining normal kidney function.
Mitochondrial DNA (mtDNA) is a non-nuclear double-stranded circular DNA without introns [17]. The mitochondrial DNA copy number (mtDNA-CN) is regarded as a biomarker of mitochondrial function [18, 19], and its alteration reflects mitochondrial biogenesis and function [20]. Under environmental stress conditions (e.g., hypoxia, heat exposure, and cold temperature), reactive oxygen species levels increase in the mitochondria, which may result in a significant decrease in the mtDNA-CN [21,22,23]. In fact, under long-term heat stress conditions, tissue ATP levels and mtDNA-CN were significantly decreased in the liver of broilers [24]. Since the kidney is a high-energy organ containing a large amount of mitochondria, we hypothesize that heat stress induces severe renal mitochondrial damage in hens during the laying period.
In pathological states of acute and chronic kidney disease, mtDNA stress may contribute to cyclic guanosine monophosphate-adenosine monophosphate synthase (cGAS) stimulator of interferon genes (STING) pathway activation and type I IFN responses [25, 26]. STING is a key adaptor in the cytosolic DNA-directed signaling pathway [27, 28] and its activity is associated with several inflammation-related diseases [29,30,31]. The leakage of mtDNA from damaged mitochondria into the cytosol is a key trigger for the activation of the STING signaling pathway [32]. In laying hens, the role of the mtDNA-cGAS-STING pathway in renal inflammation and/or fibrosis has not been clarified yet.
Therefore, the objective of this study was to clarify the effect of chronic heat stress on renal damage in laying hens, with a particular focus on the involvement of renal fibrosis and mitochondrial dysfunction.
Material and methods
Ethics statement
All procedures were approved by the Animal Care Committee of the Institute of Livestock and Grassland Science, National Agriculture and Food Research Organization (NARO), Japan (Approval number: 21C118ILGS).
Birds
The experiment consisted of a 4-week preliminary breeding period for adaptation and a 4-week experimental period. During the preliminary breeding period, the egg production status of 96 hens was recorded, and 16 laying hens (32 weeks old, i.e., the peak time of egg laying) with approximately the same body weight (1,580 ± 30 g), feed consumption rate, and egg production performance (average laying rate: 99.1%) were selected. The laying hens were raised individually in wire-floored cages (measuring 33 cm × 45 cm × 40 cm, width × height × depth) and fed with a corn-soybean meal-based diet (containing 0.3% non-phytate P, 3.3% calcium, 500 IU/kg vitamin D, 2.8 Mcal/kg ME, and 15.5% crude protein: Table 1). The basal diet was designed to meet or exceed all nutrients requirements recommended by the Japanese feeding standard for poultry [33]. They had free access to feed and fresh water. Birds were randomly divided into two group (n = 8). One group was exposed to heat stress (33 °C for 4 weeks), whereas the other group was maintained at 24 °C. The light regimen was 15 L:9 D and the dark period was from 19:00 to 04:00. Egg production and egg weight of each laying hen were recorded daily. Laying rate, average egg weight, and daily egg production were calculated. Once a week, the eggs were collected to determine the breaking eggshell strength, eggshell thickness, and egg weight using a digital egg tester (Model DET6500, NABEL Co., Ltd., Kyoto, Japan). Body weight and feed intake were recorded once a week and on the final day of the experimental period. Blood collection was performed from the brachial vein. The samples were stored in microtubes and centrifuged under refrigeration. All birds were euthanized, and renal tissue samples were removed as quickly as possible.
Plasma analysis
Plasma was separated and stored at −20 °C until assayed. The plasma levels of calcium, phosphate, blood urea nitrogen (BUN), creatine, and albumin were analyzed using the biochemical auto-analyzer, BioMajesty JCA-BM 8060 (JEOL Ltd., Tokyo, Japan).
Histological analysis and fibrosis area analysis
Renal tissues were fixed in 4% paraformaldehyde, dehydrated in 70%, 80%, 90%, 95%, and 100% ethanol, and embedded in paraffin. Paraffin-embedded tissues were sectioned at 4 μm, rehydrated in a series of xylene and ethanol solutions, and then used for Masson Trichrome staining, which stains normal tissue regions red, nuclei black, and fibrosis regions blue. Observations of histopathological changes in kidney tissues were performed by light microscopy (Leica, Nusslock, Germany). Eight fields per sample were randomly selected for fibrotic area quantification using Image J software, version 6.0 (Media Cybernetics, Inc., Rockville, MD, USA). Images were acquired under identical conditions at the same magnification. The fibrotic area was expressed as the percentage of the captured image area.
Total RNA isolation, cDNA synthesis, and real-time polymerase chain reaction (PCR)
Total RNA was extracted from kidney samples using the RNeasy Mini Kit (Qiagen, Venlo, Netherlands) following the manufacturer’s instructions. Complementary DNA (cDNA) was synthesized from 1 μg of total RNA using random primers (TOYOBO, Tokyo, Japan) and Rever Tra Ace (TOYOBO). Real-time PCR was performed to measure mRNA expression levels using a QuantStudio 5 Real-time PCR system (Applied Biosystems, Foster City, CA, USA) and THUNDERBIRD SYBR qPCR Master Mix (TOYOBO, Tokyo, Japan). The primer sequences for the target and reference genes are shown in Table 2. PCR primers for chicken interleukin (IL)-12 were purchased from Qiagen.
Determination of mtDNA relative expression and copy number
Mitochondrial DNA was extracted from kidney samples using the DNeasy blood and tissue kit (Qiagen, Venlo, Netherlands) following the manufacturer’s instructions. All steps were completed at room temperature and each sample was processed at one time. Relative expression of mtDNA was measured using a QuantStudio 5 Real-time PCR system (Applied Biosystems, Foster City, CA, USA) using THUNDERBIRD SYBR qPCR Master Mix (TOYOBO, Tokyo, Japan). The primer sequences for the target and reference genes are shown in Table 3. The mtDNA copy number was determined using the equation copies = 2^(−Ctmt)/(−Ctreference).
Tissue ATP contents
Cellular ATP in kidney tissue was extracted using the ATP assay kit (TA100, Toyo B Net, Tokyo, Japan). Briefly, small pieces of tissue (about 0.1 g) were washed once with PBS, resuspended in ATP extraction reagent, and centrifuged at 1,000 × g for 10 min. The supernatant was used for the ATP assay. The ATP level was quantitated using an ATP assay kit with luciferin and luciferase according to the manufacturer’s instructions.
Statistical analysis
All data were analyzed using a Student’s t-test. The individual laying hen was the experimental unit. Data are shown as the mean ± SE. The results were considered significant at P ≤ 0.05 and a trend at 0.05 < P ≤ 0.1.
Results
Effects of chronic heat stress on laying performance and eggshell quality
As shown in Table 4, chronic heat exposure resulted in a lower laying rate (%), egg weight (g), and daily egg production (g/d) during the experimental period (P < 0.05). Heat exposure also reduced eggshell strength (kg/cm2), thickness (mm), and eggshell weight (g). The results indicate that heat stress was induced in this study. In addition, plasma calcium and phosphate concentration were decreased when the birds were exposed to high temperature compared with the control group.
Effect of chronic heat stress on renal function and histology
While the BUN in plasma was not affected adversely, chronic heat exposure significantly increased the level of plasma creatinine and decreased the level of plasma albumin, indicating renal dysfunction (Fig. 1a). As shown in Fig. 1b, Masson’s trichrome staining revealed that the renal fibrosis area was significantly increased in the heat-stressed group. Using quantitative PCR analysis, gene expression levels of collagen type I alpha 1 (COL1A1), α-smooth muscle actin (αSMA), and transforming growth factor-β (TGF-β) were increased in the heat-stressed group (Fig. 1c). These data suggest that heat exposure induces renal dysfunction and fibrosis in laying hens.
Effect of chronic heat stress on mitochondrial function in the kidney
As shown in Fig. 2a, chronic heat exposure significantly decreased ATP content of the renal tissue. Quantitative PCR analysis was used to analyze mitochondrial DNA copy number (mtDNA-CN) in the renal tissue of laying hens based on the mitochondrial ND4, COX1, ATP6, and ND6 genes. The ratio of mt/nuclear DNA was significantly decreased for the ND4, ATP6, and ND6 genes in heat-stressed birds (Fig. 2b).
Effect of chronic heat stress on the expression of cGAS-STING pathway genes and related factors
As shown in Fig. 3a, the expression of the MDA5, STING, IRF7, and MAVS genes associated with the cGAS-STING pathway and the corresponding regulatory NF-kB gene were significantly increased in the heat-stressed group compared with that in the control group. Furthermore, the expression levels of pro-inflammatory cytokines (IL-12) and chemokines (CCL4 and CCL20) were significantly upregulated, and the expression of IL-8 tended to increase in heat-stressed hens (Fig. 3b). In contrast, the expression of other pro-inflammatory cytokines and chemokines (IFN-β, IFN, IL-1β and CCL2) was not altered by heat exposure (Fig. 3b). These results indicate that heat exposure stimulates the cGAS-STING pathway and subsequent inflammation.
Discussion
Heat exposure is a nonspecific stressor that can affect the welfare of livestock and cause death [39]. In the present study, we focused on renal damage in hens during the laying period. Chronic heat stress in laying hens increased plasma creatinine and decreased albumin levels, indicating that chronic heat exposure causes renal failure. Furthermore, heat stress in laying hens significantly increased the renal cortical fibrotic area and the expression of pro-fibrotic genes. To our knowledge, this is the first report demonstrating that heat stress induces renal fibrosis in laying hens. The results suggest that renal failure and fibrosis are responsible, at least in part, for the reduction of laying performance and eggshell quality during conditions of heat stress.
Renal fibrosis is a common pathological feature of chronic renal injury [40, 41]. A recent study indicated that mitochondrial dysfunction is a major problem in the development and progression of renal fibrosis [42]. In addition, studies have provided evidence of a relationship between mitochondrial damage and dysregulated quality of mtDNA [43, 44]. mtDNA-CN refers to the abundance of mitochondria in a cell which depends on energy requirements and can be measured by mtDNA copy number and quality of mtDNA fragments [45]. Low tissue mtDNA-CN is associated with higher levels of oxidative stress and is a causative factor for oxidative stress-related damage [46]. Heat stress affects mitochondrial function and is characterized by increased levels of reactive oxygen species and an imbalance in the mitochondrial redox state [47]. Zhang et al. [48] showed that mtDNA-CN and ATP were decreased in the liver of broiler chickens subjected to chronic heat exposure. Similarly, our results demonstrate that mtDNA-CN in chronic heat-stressed hen kidneys was significantly reduced compared with that of the control group. Moreover, ATP content was also significantly lower in heat-stressed hen kidneys compared with that in the unexposed hens. Thus, chronic heat stress leads to severe mitochondrial damage in the kidneys of laying hens, which may contribute to the progression of renal fibrosis and dysfunction.
Recently, Maekawa et al. [26] concluded that mitochondrial dysfunction and activation of the mtDNA-cGAS-STING pathway are critical regulators of mammalian kidney injury. Cyclic guanosine monophosphate-adenosine monophosphate synthase (cGAS) has recently been identified as key cytosolic DNA signal that mediates type I IFN signaling in autoimmune diseases [49]. The leakage of DNA itself from the nucleus or mitochondria into the cytosol under conditions of stress or cellular injury can cleave cGAS which converts ATP and GTP to the second messenger cyclic GAMP which mediates the activation of STING [50]. To identify the underlying mechanisms of renal fibrosis in heat-stressed hens, we measured the expression of cGAS-STING pathway-related genes by qRT-PCR. We found that the expression of the MDA5, STING, IRF7, MAVS and NF-κB genes was increased in the heat-stressed group. Furthermore, the expression of pro-inflammatory cytokine (IL-12) and chemokine (IL-8, CCL4, and CCL20) genes was upregulated in heat-stressed hens. These results indicate that the activation of the mtDNA-cGAS-STING pathway and subsequent inflammation was induced in the kidneys of heat-stressed laying hens. This suggests that in the laying hens, similar to mammals, mtDNA is a key driver of inflammation and a cellular mechanism involved in the development of inflammation and renal dysfunction. In the present study, mRNA levels of pro-inflammatory cytokine and chemokines were upregulated by chronic heat stress in the kidneys of laying hens. Both pro-inflammatory cytokines and chemokines affect the onset and progression of renal disease [51]. IL-12 promotes renal injury through IFN-γ secretion and crescent formation in a mouse model of lymphocyte accumulation [52,53,54]. In addition, serum and renal IL-12 levels are increased in patients with kidney disease [55, 56]. Chemokines stimulate the migration of immune cells and increase the production and activity of adhesion molecules that contribute to fibrosis and kidney damage [36, 57]. In humans, increased expression of the IL-8, CCL4, and CCL20 genes are involved in the pathogenesis of renal diseases [58,59,60]. Our data showing high levels of pro-inflammatory cytokine and chemokine gene expression in heat-stressed hens indicates that the release of these cytokines contributes to the progression of renal fibrosis and failure.
Conclusions
Our results indicate that chronic heat exposure induces renal fibrosis and mitochondrial damage in laying hens. Mitochondrial damage by heat stress activates mtDNA-cGAS-STING signaling and subsequent inflammation, which contributes to the progression of renal fibrosis and dysfunction. Because renal mitochondrial damage induces renal fibrosis through activation of mtDNA-cGAS-STING pathway, mitochondria-targeting compounds or STING pathway inhibitors may represent a strategy to treat renal fibrosis and dysfunction after exposure to heat stress in laying hens.
Availability of data and materials
All data generated or analyzed during this study are available from the corresponding authors on reasonable request.
Abbreviations
- ATP6:
-
ATP synthase F0 subunit 6
- αSMA:
-
α-Smooth muscle actin
- CCL2:
-
C–C motif chemokine ligands 2
- CCL4:
-
C–C motif chemokine ligands 4
- CCL20:
-
C–C motif chemokine ligands 20
- cGAS:
-
Cyclic GMP-AMP synthase
- COL1A1:
-
Collagen type I alpha 1
- COL1A2:
-
Collagen type I alpha 2
- COX1:
-
Mitochondrial cytochrome c oxidase 1
- IFN-β:
-
Type I interferon-β
- IFN-γ:
-
Type I interferon-γ
- IL-1β:
-
Interleukin-1β
- IL-8:
-
Interleukin-8
- IRF7:
-
Type I interferon regulatory factor 7
- MAVS:
-
Mitochondrial antiviral signaling
- MDA5:
-
Melanoma differentiation-associated gene 5
- mtDNA-CN:
-
Mitochondrial DNA copy number
- ND4:
-
NADH dehydrogenase subunit 4
- ND6:
-
NADH dehydrogenase subunit 6
- STING:
-
Stimulator of interferon genes
- TGF-β:
-
Transforming growth factor-β
- 18S rRNA:
-
18S ribosomal RNA
References
Wasti S, Sah N, Mishra B. Impact of heat stress on poultry health and performances, and potential mitigation strategies. Animals. 2020;10:1266. https://doi.org/10.3390/ani10081266.
Lara LJ, Rostagno MH. Impact of heat stress on poultry production. Animals. 2013;3:356–69.
Al-Saffar AA, Rose SP. Ambient temperature and the egg laying characteristics of laying fowl. Worlds Poult Sci J. 2002;58:317–31.
Allahverdi A, Feizi A, Takhtfooladi HA, Nikpiran H. Effects of heat stress on acid-base imbalance, plasma calcium concentration, egg production and egg quality in commercial layers. Glob Vet. 2013;10:203–7.
Scott TA, Balnave D. Comparison between concentrated complete diets and self-selection for feeding sexually-maturing pullets at hot and cold temperatures. Br Poult Sci. 1988;29:613–26.
Kim CH, Paik IK, Kil DY. Effects of increasing supplementation of magnesium in diets on productive performance and eggshell quality of aged laying hens. Biol Trace Elem Res. 2013;151:38–42.
Wei K, Yin Z, Xie Y. Roles of the kidney in the formation, remodeling and repair of bone. J Nephrol. 2016;29:349–57.
Blaine J, Chonchol M, Levi M. Renal control of calcium, phosphate, and magnesium homeostasis. Clin J Am Soc Nephrol. 2015;10:1257–72.
Vafai SB, Mootha VK. Mitochondrial disorders as windows into an ancient organelle. Nature. 2012;491:374–83.
Ray PD, Huang BW, Tsuji Y. Reactive oxygen species (ROS) homeostasis and redox regulation in cellular signaling. Cell Signal. 2012;24:981–90.
Hsu CC, Tseng LM, Lee HC. Role of mitochondrial dysfunction in cancer progression. Exp Biol Med. 2016;241:1281–95.
Manolis AS, Manolis AA, Manolis TA, Apostolaki NE, Apostolopoulos EJ, Melita H, et al. Mitochondrial dysfunction in cardiovascular disease: current status of translational research/clinical and therapeutic implications. Med Res Rev. 2021;41:275–313.
Misrani A, Tabassum S, Yang L. Mitochondrial dysfunction and oxidative stress in Alzheimer’s disease. Front Aging Neurosci. 2021;13:617588.
Schapira AHV. Oxidative stress and mitochondrial dysfunction in neurodegeneration. Curr Opin Neurol. 1996;9:260–4.
Jang JY, Blum A, Liu J, Finkel T. The role of mitochondria in aging. J Clin Invest. 2018;128:3662–70.
Ishimoto Y, Inagi R. Mitochondria: a therapeutic target in acute kidney injury. Nephrol Dial Transplant. 2016;31:1062–9.
Taanman JW. The mitochondrial genome: structure, transcription, translation and replication. Biochim Biophys Acta BBA - Bioenerg. 1999;1410:103–23.
Lee HC, Wei YH. Mitochondrial biogenesis and mitochondrial DNA maintenance of mammalian cells under oxidative stress. Int J Biochem Cell Biol. 2005;37:822–34.
Santacruz K, Lewis J, Spires T, Paulson J, Kotilinek L, Ingelsson M, et al. Medicine: Tau suppression in a neurodegenerative mouse model improves memory function. Science. 2005;309:476–81.
Castellani CA, Longchamps RJ, Sun J, Guallar E, Arking DE. Thinking outside the nucleus: mitochondrial DNA copy number in health and disease. Mitochondrion. 2020;53:214–23.
Soto P, Smith LC. BH4 peptide derived from Bcl-xL and Bax-inhibitor peptide suppresses apoptotic mitochondrial changes in heat stressed bovine oocytes. Mol Reprod Dev. 2009;76:637–46.
Loeb LA, Wallace DC, Martin GM. The mitochondrial theory of aging and its relationship to reactive oxygen species damage and somatic mtDNA mutations. Proc Natl Acad Sci. 2005;102:18769–70.
Kuo CW, Tsai MH, Lin TK, Tiao MM, Wang PW, Chuang JH, et al. mtDNA as a mediator for expression of hypoxia-inducible factor 1α and ROS in hypoxic neuroblastoma cells. Int J Mol Sci. 2017;18:1220. https://doi.org/10.3390/ijms18061220.
Zhang X, Wang T, Ji J, Wang H, Zhu X, Du P, et al. The distinct spatiotemporal distribution and effect of feed restriction on mtDNA copy number in broilers. Sci Rep. 2020;10:3240.
Chung KW, Dhillon P, Huang S, Sheng X, Shrestha R, Qiu C, et al. Mitochondrial damage and activation of the STING Pathway lead to renal inflammation and fibrosis. Cell Metab. 2019;30:784–99. https://doi.org/10.1016/j.cmet.2019.08.003.
Maekawa H, Inoue T, Ouchi H, Jao TM, Inoue R, Nishi H, et al. Mitochondrial damage causes inflammation via cGAS-STING signaling in acute kidney injury. Cell Rep. 2019;29:1261–73.
Wu J, Sun L, Chen X, Du F, Shi H, Chen C, et al. Cyclic GMP-AMP is an endogenous second messenger in innate immune signaling by cytosolic DNA. Science. 2013;339:826–30.
Ablasser A, Goldeck M, Cavlar T, Deimling T, Witte G, Röhl I, et al. cGAS produces a 2′-5′-linked cyclic dinucleotide second messenger that activates STING. Nature. 2013;498:380–4.
Canesso MCC, Lemos L, Neves TC, Marim FM, Castro TBR, Veloso É, et al. The cytosolic sensor STING is required for intestinal homeostasis and control of inflammation. Mucosal Immunol. 2018;11(3):820–34.
Guo Y, Gu R, Gan D, Hu F, Li G, Xu G. Mitochondrial DNA drives noncanonical inflammation activation via cGAS–STING signaling pathway in retinal microvascular endothelial cells. Cell Commun Signal. 2020;18:172. https://doi.org/10.1186/s12964-020-00637-3.
Yu H, Zou W, Wang X, Dai G, Zhang T, Zhang G, et al. Research Note: Correlation analysis of interleukin-6, interleukin-8, and C-C motif chemokine ligand 2 gene expression in chicken spleen and cecal tissues after Eimeria tenella infection in vivo. Poult Sci. 2020;99:1326–31.
West AP, Shadel GS, Ghosh S. Mitochondria in innate immune responses. Nat Rev Immunol. 2011;11:389–402.
NARO (National Agriculture and Food Research Organization). Japanese Feeding Standard for Poultry, 2011. Tokyo: Japan Livestock Industry Association; 2012.
Feng Y, Hu Y, Hou Z, Sun Q, Jia Y, Zhao R. Chronic corticosterone exposure induces liver inflammation and fibrosis in association with m6A-linked post-transcriptional suppression of heat shock proteins in chicken. Cell Stress Chaperones. 2020;25:47–56.
Li M, Raheem MA, Han C, Yu F, Dai Y, Imran M, et al. The fowl adenovirus serotype 4 (FAdV-4) induce cellular pathway in chickens to produce interferon and antigen-presented molecules (MHCI/II). Poult Sci. 2021;100(10):101406.
Hong Y, Lee J, Vu TH, Lee S, Lillehoj HS, Hong YH. Chicken avian β-defensin 8 modulates immune response via the mitogen-activated protein kinase signaling pathways in a chicken macrophage cell line. Poult Sci. 2020;99:4174–82.
Li YP, Bang DD, Handberg KJ, Jorgensen PH, Man FZ. Evaluation of the suitability of six host genes as internal control in real-time RT-PCR assays in chicken embryo cell cultures infected with infectious bursal disease virus. Vet Microbiol. 2005;110:155–65.
Lu MY, Wang WW, Qi GH, Xu L, Wang J. Mitochondrial transcription factor A induces the declined mitochondrial biogenesis correlative with depigmentation of brown eggshell in aged laying hens. Poult Sci. 2021;100(3):100811.
Chen S, Yong Y, Ju X. Effect of heat stress on growth and production performance of livestock and poultry: Mechanism to prevention. J Therm Biol. 2021;99:103019.
Kitamura M, Mochizuki Y, Miyata Y, Obata Y, Mitsunari K, Matsuo T, et al. Pathological characteristics of periodontal disease in patients with chronic kidney disease and kidney transplantation. Int J Mol Sci. 2019;20:3413. https://doi.org/10.3390/ijms20143413.
Yan H, Xu J, Xu Z, Yang B, Luo P, He Q. Defining therapeutic targets for renal fibrosis: Exploiting the biology of pathogenesis. Biomed Pharmacother. 2021;143:112115.
Miao J, Liu J, Niu J, Zhang Y, Shen W, Luo C, et al. Wnt/β-catenin/RAS signaling mediates age-related renal fibrosis and is associated with mitochondrial dysfunction. Aging Cell Aging Cell. 2019;18(5):e13004.
Joseph AM, Adhihetty PJ, Wawrzyniak NR, Wohlgemuth SE, Picca A, Kujoth GC, et al. Dysregulation of mitochondrial quality control processes contribute to Sarcopenia in a mouse model of premature aging. PLoS ONE. 2013;8:e69327.
Kolesar JE, Safdar A, Abadi A, MacNeil LG, Crane JD, Tarnopolsky MA, et al. Defects in mitochondrial DNA replication and oxidative damage in muscle of mtDNA mutator mice. Free Radic Biol Med. 2014;75:241–51.
Jeng JY, Yeh TS, Lee JW, Lin SH, Fong TH, Hsieh RH. Maintenance of mitochondrial DNA copy number and expression are essential for preservation of mitochondrial function and cell growth. J Cell Biochem. 2008;103:347–57.
Liu CS, Tsai CS, Kuo CL, Chen HW, Lii CK, Ma YS, et al. Oxidative stress-related alteration of the copy number of mitochondrial DNA in human leukocytes. Free Radic Res. 2003;37(12):1307–17.
Huang C, Jiao H, Song Z, Zhao J, Wang X, Lin H. Heat stress impairs mitochondria functions and induces oxidative injury in broiler chickens. J Anim Sci. 2015;93:2144–53.
Zhang J, Bai KW, He J, Niu Y, Lu Y, Zhang L, et al. Curcumin attenuates hepatic mitochondrial dysfunction through the maintenance of thiol pool, inhibition of mtDNA damage, and stimulation of the mitochondrial thioredoxin system in heat-stressed broilers. J Anim Sci. 2018;96:867–79.
Lood C, Blanco LP, Purmalek MM, Carmona-Rivera C, De Ravin SS, Smith CK, et al. Neutrophil extracellular traps enriched in oxidized mitochondrial DNA are interferogenic and contribute to lupus-like disease. Nat Med. 2016;22:146–53.
Sun L, Wu J, Du F, Chen X, Chen ZJ. Cyclic GMP-AMP Synthase is a cytosolic DNA sensor that activates the Type I interferon pathway. Science. 2013;339:786–91.
Silverstein DM. Inflammation in chronic kidney disease: role in the progression of renal and cardiovascular disease. Pediatr Nephrol. 2009;24:1445–52.
Schwarting A, Tesch G, Kinoshita K, Maron R, Weiner HL, Kelley VR. IL-12 drives IFN-γ-dependent autoimmune kidney disease in MRL-Fas(lpr) mice. J Immunol. 1999;163:6884–91.
Kitching AR, Turner AL, Wilson GRA, Semple T, Odobasic D, Timoshanko JR, et al. IL-12p40 and IL-18 in crescentic glomerulonephritis: IL-12p40 is the key Th1-defining cytokine chain, whereas IL-18 promotes local inflammation and leukocyte recruitment. J Am Soc Nephrol. 2005;16:2023–33.
Zheng N, Xie K, Ye H, Dong Y, Wang B, Luo N, et al. TLR7 in B cells promotes renal inflammation and Gd-IgA1 synthesis in IgA nephropathy. JCI Insight. 2020;5:e136965.
Yong K, Ooi EM, Dogra G, Mannion M, Boudville N, Chan D, et al. Elevated interleukin-12 and interleukin-18 in chronic kidney disease are not associated with arterial stiffness. Cytokine. 2013;64:39–42.
Romanova Y, Laikov A, Markelova M, Khadiullina R, Makseev A, Hasanova M, et al. Proteomic analysis of human serum from patients with chronic kidney disease. Biomolecules. 2020;10:257. https://doi.org/10.3390/biom10020257.
Le Y, Zhou Y, Iribarren P, Wang J. Chemokines and chemokine receptors: their manifold roles in homeostasis and disease. Cell Mol Immunol. 2004;1:95–104.
Kim HS, Lee JS, Lee HK, Park EJ, Jeon HW, Kang YJ, et al. Mesenchymal stem cells ameliorate renal inflammation in Adriamycin-induced nephropathy. Immune Netw. 2019;19:e36.
Zuo Z, Huang P, Jiang Y, Zhang Y, Zhu M. Acupuncture attenuates renal interstitial fibrosis via the TGF-β/Smad pathway. Mol Med Rep. 2019;20:2267–75.
Han L, Zou Y, Yu C. Targeting CC chemokine ligand (CCL) 20 by miR-143-5p alleviate lead poisoning-induced renal fibrosis by regulating interstitial fibroblasts excessive proliferation and dysfunction. Bioengineered. 2022;13:11156–68.
Acknowledgements
The authors would like to thank Enago (www.enago.jp) for the English language review.
Funding
This study was supported by Japan Society for the Promotion of Science KAKENHI Grant Number JP21K14966 to F.H., the Environment Research and Technology Development Fund (JPMEERF20S11820) of the Environmental Restoration and Conservation Agency of Japan.
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FH wrote the main text of the manuscript and collected the data, contributed to the design and helped in drafting of the paper. FH and HO carried out the animal experiments. FH, MY, HM, and HO contributed to sample collection. HO aided in interpreting the results and worked on the manuscript. All authors read and approved the final manuscript.
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All procedures were approved by the Animal Care Committee of the Institute of Livestock and Grassland Science, NARO, Japan (Approval number: 21C118ILGS).
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Not applicable.
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Nanto-Hara, F., Yamazaki, M., Murakami, H. et al. Chronic heat stress induces renal fibrosis and mitochondrial dysfunction in laying hens. J Animal Sci Biotechnol 14, 81 (2023). https://doi.org/10.1186/s40104-023-00878-5
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DOI: https://doi.org/10.1186/s40104-023-00878-5